A groove assembly for holding at least one fiber optic. The assembly includes a base, a cover and a small carrier disposed between the base and the cover. The carrier has at least one groove. At least one fiber optic is disposed in this groove and terminates at an edge surface of the carrier. The base and cover have respective edge surfaces serving as attachment surfaces for attachment of the assembly to a planar lightwave circuit (PLC). The PLC has at least one waveguide terminating at an edge, to which the fiber requires alignment. The base and/or cover are preferably formed from a material enabling attachment to the PLC, e.g., transparent to energy used for curing an adhesive. The carrier is formed from material enabling a substantially more precise formation of the grooves, e.g., silicon.
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1. An assembly for coupling at least one fiber optic to an optical device, comprising:
a base; a cover; a carrier disposed between the base and the cover, having at least one groove formed therein; at least one fiber optic disposed in a respective groove of the at least one groove, and therefore between the carrier and the base or cover, and terminating at an edge surface of the carrier; and a planar lightwave circuit (PLC) having at least one waveguide running to an edge thereof; wherein mating surfaces of the PLC are attached to edge surfaces of the base and cover above and below the carrier, such that the at least one fiber optic is aligned to the at least one waveguide.
10. A method for fabricating an assembly for coupling at least one fiber optic to an optical device, comprising:
providing a base and a cover; disposing a carrier between the base and the cover, the carrier having at least one groove formed therein; disposing at least one fiber optic in a respective groove of the at least one groove, and therefore between the carrier and the base or cover, and terminating at an edge surface of the carrier; and attaching mating surfaces of a planar lightwave circuit (PLC) to edge surfaces of the base and the cover above and below the carrier, wherein the PLC has at least one waveguide running to the edge thereof that is aligned with one fiber optic.
24. A method for holding at least one fiber optic, for attachment to a device having at least one waveguide terminating at an edge thereof, and to which the at least one fiber is to be aligned, comprising:
using a groove assembly, including a base and a cover, and a carrier between the base and the cover, the carrier having at least one groove formed therein; disposing at least one fiber optic in a respective groove of the at least one groove, and therefore between the carrier and the base or cover, and terminating at an edge surface of the carrier; aligning a fiber optic in the groove assembly to a waveguide in said device; and attaching the device and the assembly via edge surfaces of the base and the cover, and respective mating surfaces of the PLC above and below the carrier.
2. The assembly of
3. The assembly of
4. The assembly of
6. The assembly of
7. The assembly of
8. The assembly of
9. The assembly of
11. The method of
12. The method of
13. The method of
15. The method of
16. The method of
illuminating the respective edge surfaces of the base and cover and the respective mating surfaces of the PLC with energy, through the base and the cover, to cure said adhesive.
17. The method of
18. The method of
19. The method of
illuminating one of the respective edge surfaces of the base and cover with energy, through the block, to cure said adhesive.
20. The method of
illuminating the respective edge surfaces of the base and cover and the respective mating surfaces of the PLC with energy, through the base and the cover, to cure an adhesive used to adhere the respective edge surfaces of the base and cover to the PLC.
21. The method of
22. The method of
illuminating one of the respective edge surfaces of the base and cover with energy, through the block, to cure an adhesive used to adhere the edge surface of the cover to the PLC.
23. The method of
25. The method of
26. The method of
27. The method of
29. The method of
31. The method of
illuminating the respective edge surfaces of the base and cover and the respective mating surfaces of the PLC with energy, through the base and the cover, to cure said adhesive.
32. The method of
33. The method of
34. The method of
illuminating one of the respective edge surfaces of the base and cover with energy, through the block, to cure said adhesive.
36. The method of
illuminating the respective edge surfaces of the base and cover and the respective mating surfaces of the PLC with energy, through the base and the cover, to cure an adhesive.
37. The method of
38. The method of
illuminating one of the respective edge surfaces of the base and cover with energy, through the block, to cure said adhesive.
39. The method of
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The present invention relates to fiber optics. More particularly, the present invention relates to a technique for precise alignment and attachment of fiber optics to planar lightwave circuits (PLCs).
Fiber optic communication links employ in-line, optical components for various operations including amplification, attenuation, multiplexing, demultiplexing, etc. These components are often formed from planar lightwave circuits (PLCs), within which various structures are used to perform the requisite optical signal processing operations.
PLCs are usually wafer-based modules formed using various silicon-based semiconductor formation techniques including growth, deposition and etching. The upper layers of PLCs usually employ waveguides (e.g., silica-on-silicon), deposited and etched, through which the optical signals are transmitted. For effective use in fiber optic systems, the PLC waveguides must be interfaced to fiber optics, which carry the optical signals to and from the PLC.
To ensure quality signal transmission to and from the PLC, the fiber optics must be precisely aligned to the PLC waveguides. Any misalignment will result in signal insertion loss, which is highly undesirable in optical networks because it directly impacts the distance over which the optical signals can travel. Equally important are the techniques used to attach the fiber optics to the PLC. Rigid attachment is required to maintain alignment over the life of the component, and through various environmental conditions. The techniques chosen for alignment and attachment are highly interrelated since they will be implemented on the same sub-assembly, and thus must be carefully, and compatibly implemented, while keeping the costs of the sub-assembly to acceptable levels.
What is required, therefore, are improved techniques for aligning and attaching fiber optics to PLC waveguides, which are compatible and which can be implemented at reasonable costs.
These requirements are met, and further advantages are provided, by the present invention which in one aspect is a groove assembly for holding at least one fiber optic, and methods for its fabrication and use. The assembly includes a base, a cover and a carrier disposed between the base and the cover. The carrier has at least one groove. At least one fiber optic is disposed in this groove, and therefore between the carrier and the base or cover, and terminates at an edge surface of the carrier. The base and cover have respective edge surfaces serving as attachment surfaces for attachment of the groove assembly to a device with at least one waveguide terminating at an edge thereof, to which the fiber (or array of fibers) is to be aligned.
The base and/or cover are preferably formed from a first material enabling attachment of the assembly to the device, e.g., a material transparent to energy to be directed through the material for curing an adhesive used to adhere the respective edge surfaces of the base and cover to the device. The carrier is formed from a second material enabling a substantially more precise formation of the grooves than would the first material, e.g., silicon, which enables precise formation of the grooves.
The assembly is especially adapted for attachment to the edge of a planar lightwave circuit (PLC). The PLC has at least one waveguide running to the edge thereof, and the assembly is attached via the respective edge surfaces of the base and cover, and respective mating surfaces of the PLC, using an adhesive, such that the fiber optic is aligned to the waveguide. The PLC may also include a block, to form one of the mating surfaces. This block may also be formed from a material transparent to energy to be directed through the material for curing the adhesive.
The combination of the small silicon carrier, between the transparent base and cover, offers distinct advantages over prior techniques. High precision groove formation is possible in the silicon, thus improving optical performance. The small piece of silicon (5 mm vs. 12 mm) decreases costs. Finally, larger, transparent base and cover pieces provide at least two adhesion points and other structural integrity.
The subject matter which is regarded as the invention is particularly pointed out and distinctly claimed in the concluding portion of the specification. The invention, however, both as to organization and method of practice, together with further objects and advantages thereof, may be best understood by reference to the following detailed description of the preferred embodiment(s) and the accompanying drawings in which:
With reference to
In the exemplary demultiplexing application shown, input fiber optic 34 is interfaced to substrate 20 using a glass or silicon v-groove block assembly 35. Multiple output fibers 36 are also interfaced to the substrate 20 using a similar block assembly 37.
With reference now to the side, cross-sectional view of
Side views of the v-groove fiber assemblies 35 and 37 are also apparent here. These assemblies are usually assembled before their attachment to the PLC, and their insertion into the package. Their main function is the interface between the fiber optics 34/36, and optical waveguides running to the edges of PLC 20.
One embodiment of exemplary groove assembly 35 is depicted in greater detail in the cross-sectional views of
A similar side, cross-sectional view is shown in
Some performance considerations are evident when choosing these attachment and alignment techniques. First, to ensure fiber placement accuracy in the grooves of base 39, these grooves should be formed precisely. In this exemplary glass embodiment, the grooves are usually machined into the upper surface of the base, to an accuracy of about +/-0.05 μm (micrometer) groove pitch tolerance. This may not be optimal tolerance, but the glass base does provide other notable advantages: it is strong yet transparent, thus allowing UV light energy transmission to attachment point 64 (represented as the dashed lines in the enlarged view of
Another similar embodiment is shown in
By using silicon as the base material, much more precise groove formation is possible than with glass, e.g., +/-0.025 μm groove pitch tolerance, thus the fibers are aligned and coupled to the PLC waveguides with much greater accuracy. The groove formation can be done with known silicon processing techniques, including deposition, masking, etching, etc. However, this amount of silicon (e.g., more than 12 mm in the lateral direction shown) leads to more expense, though somewhat offset by the improved processing costs and yields over glass v-groove machining (especially at high volumes). Also (as shown in
In accordance with the present invention, and with reference to the side cross-sectional views of
This carrier is, for example, about 750 μm thick, and about 5 mm along its lateral dimension (i.e., much smaller than the 12 mm silicon base of
Because the carrier is disposed between the transparent base and cover, two attachment points 262 and 264 are provided along interface 260. As shown in
The invention is applicable to single input or output fibers, or large fiber arrays. The term "groove" is used broadly herein to connote any type of cavity structure within carrier 231 suitable for holding a longitudinal fiber optic, and includes (without limitation) v-grooves, u-grooves, rectangular grooves, through-tubes, or any similar structures.
Additional detail of one embodiment of the inventive assembly is shown in the perspective view of FIG. 6. Here, the combined, polished edge comprised of base 238, carrier 231, fiber array faces, and cover 239 are shown. Particular advantages directly flow from this architecture: High precision groove formation in a material like silicon, thus improving optical performance; small piece of silicon (5 mm vs. 12 mm) thus decreasing costs; maintenance of at least two adhesion points and other structural integrity provided by the two larger transparent pieces surrounding the carrier.
While the invention has been particularly shown and described with reference to preferred embodiment(s) thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.
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